5,061 research outputs found
Characterization of Lifshitz transitions in topological nodal line semimetals
We introduce a two-band model of three-dimensional nodal line semimetals, the
Fermi surface of which at half-filling may form various one-dimensional
configurations of different topology. We study the symmetries and "drumhead"
surface states of the model, and find that the transitions between different
configurations, namely, the Lifshitz transitions, can be identified solely by
the number of gap-closing points on some high-symmetry planes in the Brillouin
zone. A global phase diagram of this model is also obtained accordingly. We
then investigate the effect of some extra terms analogous to a two-dimensional
Rashba-type spin-orbit coupling. The introduced extra terms open a gap for the
nodal line semimetals and can be useful in engineering different topological
insulating phases. We demonstrate that the behavior of surface Dirac cones in
the resulting insulating system has a clear correspondence with the different
configurations of the original nodal lines in the absence of the gap terms.Comment: 7 pages, 6 figure
Helical damping and anomalous critical non-Hermitian skin effect
Non-Hermitian skin effect and critical skin effect are unique features of
non-Hermitian systems. In this Letter, we study an open system with its
dynamics of single-particle correlation function effectively dominated by a
non-Hermitian damping matrix, which exhibits skin effect, and
uncover the existence of a novel phenomenon of helical damping. When adding
perturbations that break anomalous time reversal symmetry to the system, the
critical skin effect occurs, which causes the disappearance of the helical
damping in the thermodynamic limit although it can exist in small size systems.
We also demonstrate the existence of anomalous critical skin effect when we
couple two identical systems with skin effect. With the help of
non-Bloch band theory, we unveil that the change of generalized Brillouin zone
equation is the necessary condition of critical skin effect.Comment: 7+5 pages, 4+5 figure
A Knowledge Management performance evaluation model based on fuzzy set theory
As the knowledge-based economy time comes, the core of business process is transforming financial intensive into technology intensive and knowledge intensive gradually. However, the value of knowledge itself can’t be measured easily. We must evaluate and investigate the performance of knowledge management through activities of knowledge management process. During the performance evaluation process, many uncertain factors must be considered. It is also involved ambiguity occurred by human subjective judgment. Therefore, a performance evaluation model of knowledge management is proposed in this paper by combining Fuzzy Delphi with Fuzzy AHP. Finally, a numerical example is given to demonstrate the procedure for the proposed method at the end of this paper
Topological invariants, zero mode edge states and finite size effect for a generalized non-reciprocal Su-Schrieffer-Heeger model
Intriguing issues in one-dimensional non-reciprocal topological systems
include the breakdown of usual bulk-edge correspondence and the occurrence of
half-integer topological invariants. In order to understand these unusual
topological properties, we investigate the topological phase diagrams and the
zero-mode edge states of a generalized non-reciprocal Su-Schrieffer-Heeger
model, based on some analytical results. Meanwhile, we provide a concise
geometrical interpretation of the bulk topological invariants in terms of two
independent winding numbers and also give an alternative interpretation related
to the linking properties of curves in three-dimensional space. For the system
under the open boundary condition, we construct analytically the wavefunctions
of zero-mode edge states by properly considering a hidden symmetry of the
system and the normalization condition with the use of biorthogonal
eigenvectors. Our analytical results directly give the phase boundary for the
existence of zero-mode edge states and unveil clearly the evolution behavior of
edge states. In comparison with results via exact diagonalization of
finite-size systems, we find our analytical results agree with the numerical
results very well.Comment: 13 pages, 9 figure
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